void mexFunction(int nlhs, mxArray *plhs[], int nrhs, const mxArray *prhs[])
{
// Initiatlize Pylon
Pylon::PylonAutoInitTerm auto_init_term;
try
{
// Get the transport layer factory.
Pylon::CTlFactory& tlFactory = Pylon::CTlFactory::GetInstance();
// Get all attached devices
Pylon::DeviceInfoList_t devices;
tlFactory.EnumerateDevices(devices);
// Create an array of instant cameras for the found devices
Pylon::CInstantCameraArray cameras(devices.size());
// Init output
plhs[0] = mxCreateCellMatrix(cameras.GetSize(),2);
// Find all names
for(size_t i = 0; i < cameras.GetSize(); ++i)
{
cameras[i].Attach(tlFactory.CreateDevice(devices[i]));
mxSetCell(plhs[0],i+cameras.GetSize(),mxCreateString(cameras[i].GetDeviceInfo().GetModelName()));
mxSetCell(plhs[0],i,mxCreateDoubleScalar(i));
}
}
catch (GenICam::GenericException &e)
{
// Error handling.
mexErrMsgIdAndTxt("baslerDriver:Error:CameraError",e.GetDescription());
}
return;
}
CameraPtrList
BaslerCameraManager::detectCameras() {
// wipe the list of already detected cameras
_cameras = CameraPtrList();
// Get the transport layer factory
Pylon::CTlFactory& TlFactory = Pylon::CTlFactory::GetInstance();
// Create the transport layer object needed to enumerate or
// create a camera object of type Camera_t::DeviceClass()
Pylon::ITransportLayer *pTl = TlFactory.CreateTl(BaslerCamera_t::DeviceClass());
// Exit the application if the specific transport layer is not available
if (!pTl)
throw RuntimeError("BaslerCameraManager: Failed to create transport layer!");
// Get all attached cameras and exit the application if no camera is found
Pylon::DeviceInfoList_t devices;
if (0 == pTl->EnumerateDevices(devices))
return _cameras; // briefly, an empty list
// Create the BaslerCamera instance for each attached camera
for(Pylon::DeviceInfoList_t::iterator it = devices.begin(); it != devices.end(); it++)
{
// Create the camera object of the first available camera.
// The camera object is used to set and get all available
// camera features.
try {
BaslerCamera_t* cam = new BaslerCamera_t(pTl->CreateDevice(*it));
_cameras.push_back(new BaslerCamera(cam->GetDeviceInfo().GetSerialNumber().c_str(), cam));
} catch(GenICam::GenericException e) {
throw RuntimeError(String("BaslerCameraManager: Error occurred while trying to create Camera object:\n") + e.what());
}
}
return _cameras;
}
int main( int argc, char** argv )
{
::setenv( "PYLON_ROOT", STRINGIZED( BASLER_PYLON_DIR ), 0 );
::setenv( "GENICAM_ROOT_V2_1", STRINGIZED( BASLER_PYLON_GENICAM_DIR ), 0 );
try
{
unsigned int id;
std::string address;
std::string setAttributes;
unsigned int discard;
boost::program_options::options_description description( "options" );
unsigned int packet_size;
unsigned int exposure;
unsigned int gain;
unsigned int offset_x;
unsigned int offset_y;
unsigned int width;
unsigned int height;
std::string frame_trigger;
std::string line_trigger;
unsigned int line_rate;
double timeout_seconds;
description.add_options()
( "help,h", "display help message" )
( "address", boost::program_options::value< std::string >( &address ), "camera ip address; default: connect to the first available camera" )
( "discard", "discard frames, if cannot keep up; same as --buffer=1" )
( "buffer", boost::program_options::value< unsigned int >( &discard )->default_value( 0 ), "maximum buffer size before discarding frames, default: unlimited" )
( "list-cameras", "output camera list and exit" )
( "fields,f", boost::program_options::value< std::string >( &options.fields )->default_value( "t,rows,cols,type" ), "header fields, possible values: t,rows,cols,type,size,counters" )
( "image-type", boost::program_options::value< std::string >( &options.type )->default_value( "3ub" ), "image type, e.g. '3ub'; also see --long-help for details" )
( "offset-x", boost::program_options::value< unsigned int >( &offset_x )->default_value( 0 ), "offset in pixels in the line" )
( "offset-y", boost::program_options::value< unsigned int >( &offset_y )->default_value( 0 ), "offset in lines in the frame" )
( "width", boost::program_options::value< unsigned int >( &width )->default_value( std::numeric_limits< unsigned int >::max() ), "line width in pixels; default: max" )
( "height", boost::program_options::value< unsigned int >( &height )->default_value( std::numeric_limits< unsigned int >::max() ), "number of lines in frame (in chunk mode always 1); default: max" )
( "frame-trigger", boost::program_options::value< std::string >( &frame_trigger ), "'line1', 'line2', 'line3', 'encoder'" ) //; if absent while --line-trigger present, same as --line-trigger" )
( "line-trigger", boost::program_options::value< std::string >( &line_trigger ), "'line1', 'line2', 'line3', 'encoder'" )
( "line-rate", boost::program_options::value< unsigned int >( &line_rate ), "line aquisition rate" )
( "encoder-ticks", boost::program_options::value< unsigned int >( &encoder_ticks ), "number of encoder ticks until the counter resets (reused for line number in frame in chunk mode)" )
( "header-only", "output header only" )
( "no-header", "output image data only" )
( "packet-size", boost::program_options::value< unsigned int >( &packet_size ), "mtu size on camera side, should be not greater than your lan and network interface set to" )
( "exposure", boost::program_options::value< unsigned int >( &exposure )->default_value( 100 ), "exposure" )
( "gain", boost::program_options::value< unsigned int >( &gain )->default_value( 100 ), "gain" )
( "timeout", boost::program_options::value< double >( &timeout_seconds )->default_value( 3.0 ), " frame acquisition timeout" )
( "test-colour", "output colour test image" )
( "verbose,v", "be more verbose" );
boost::program_options::variables_map vm;
boost::program_options::store( boost::program_options::parse_command_line( argc, argv, description), vm );
boost::program_options::parsed_options parsed = boost::program_options::command_line_parser(argc, argv).options( description ).allow_unregistered().run();
boost::program_options::notify( vm );
if ( vm.count( "help" ) || vm.count( "long-help" ) )
{
std::cerr << "acquire images from a basler camera (for now gige only)" << std::endl;
std::cerr << "output to stdout as serialized cv::Mat" << std::endl;
std::cerr << std::endl;
std::cerr << "usage: basler-cat [<options>] [<filters>]" << std::endl;
std::cerr << std::endl;
std::cerr << description << std::endl;
if( vm.count( "long-help" ) )
{
std::cerr << std::endl;
std::cerr << snark::cv_mat::filters::usage() << std::endl;
std::cerr << std::endl;
std::cerr << snark::cv_mat::serialization::options::type_usage() << std::endl;
}
std::cerr << std::endl;
std::cerr << "note: there is a glitch or a subtle feature in basler line camera:" << std::endl;
std::cerr << " - power-cycle camera" << std::endl;
std::cerr << " - view colour images: it works" << std::endl;
std::cerr << " - view grey-scale images: it works" << std::endl;
std::cerr << " - view colour images: it still displays grey-scale" << std::endl;
std::cerr << " even in their native viewer you need to set colour image" << std::endl;
std::cerr << " repeatedly and with pure luck it works, but we have not" << std::endl;
std::cerr << " managed to do it in software; the remedy: power-cycle the camera" << std::endl;
std::cerr << std::endl;
return 1;
}
verbose = vm.count( "verbose" );
if( verbose )
{
std::cerr << "basler-cat: PYLON_ROOT=" << ::getenv( "PYLON_ROOT" ) << std::endl;
std::cerr << "basler-cat: GENICAM_ROOT_V2_1=" << ::getenv( "GENICAM_ROOT_V2_1" ) << std::endl;
std::cerr << "basler-cat: initializing camera..." << std::endl;
}
Pylon::PylonAutoInitTerm auto_init_term;
Pylon::CTlFactory& factory = Pylon::CTlFactory::GetInstance();
Pylon::ITransportLayer* transport_layer( Pylon::CTlFactory::GetInstance().CreateTl( Pylon::CBaslerGigECamera::DeviceClass() ) );
if( !transport_layer )
{
std::cerr << "basler-cat: failed to create transport layer" << std::endl;
std::cerr << " most likely PYLON_ROOT and GENICAM_ROOT_V2_1 environment variables not set" << std::endl;
std::cerr << " point them to your pylon installation, e.g:" << std::endl;
std::cerr << " export PYLON_ROOT=/opt/pylon" << std::endl;
std::cerr << " export GENICAM_ROOT_V2_1=/opt/pylon/genicam" << std::endl;
return 1;
}
if( vm.count( "list-cameras" ) )
{
Pylon::DeviceInfoList_t devices;
factory.EnumerateDevices( devices );
for( unsigned int i = 0; i < devices.size(); ++i ) { std::cerr << devices[i].GetFullName() << std::endl; }
return 0;
}
timeout = timeout_seconds * 1000.0;
std::string filters = comma::join( boost::program_options::collect_unrecognized( parsed.options, boost::program_options::include_positional ), ';' );
options.header_only = vm.count( "header-only" );
options.no_header = vm.count( "no-header" );
csv = comma::csv::options( argc, argv );
bool chunk_mode = csv.has_field( "counters" ) // quick and dirty
|| csv.has_field( "adjusted-t" )
|| csv.has_field( "line" )
|| csv.has_field( "line-count" )
|| csv.has_field( "ticks" )
|| csv.has_field( "counters/adjusted-t" )
|| csv.has_field( "counters/line" )
|| csv.has_field( "counters/line-count" )
|| csv.has_field( "counters/ticks" );
if( chunk_mode )
{
if( vm.count( "encoder-ticks" ) == 0 ) { std::cerr << "basler-cat: chunk mode, please specify --encoder-ticks" << std::endl; return 1; }
if( !filters.empty() ) { std::cerr << "basler-cat: chunk mode, cannot handle filters; use: basler-cat | cv-cat <filters> instead" << std::endl; return 1; }
if( height != 1 && height != std::numeric_limits< unsigned int >::max() ) { std::cerr << "basler-cat: only --height=1 implemented in chunk mode" << std::endl; return 1; }
height = 1;
std::vector< std::string > v = comma::split( csv.fields, ',' );
std::string format;
for( unsigned int i = 0; i < v.size(); ++i )
{
if( v[i] == "t" ) { v[i] = "header/" + v[i]; format += "t"; }
else if( v[i] == "rows" || v[i] == "cols" || v[i] == "size" || v[i] == "type" ) { v[i] = "header/" + v[i]; format += "ui"; }
else if( v[i] == "adjusted-t" ) { v[i] = "counters/" + v[i]; format += "t"; }
else if( v[i] == "line-count" || v[i] == "ticks" ) { v[i] = "counters/" + v[i]; format += "ul"; }
else if( v[i] == "line" ) { v[i] = "counters/" + v[i]; format += "ui"; }
else { std::cerr << "basler-cat: expected field, got '" << v[i] << "'" << std::endl; return 1; }
}
csv.fields = comma::join( v, ',' );
csv.full_xpath = true;
csv.format( format );
}
if( !vm.count( "buffer" ) && vm.count( "discard" ) ) { discard = 1; }
Pylon::CBaslerGigECamera camera;
if( vm.count( "address" ) )
{
Pylon::CBaslerGigEDeviceInfo info;
info.SetIpAddress( address.c_str() );
camera.Attach( factory.CreateDevice( info ) );
}
else
{
Pylon::DeviceInfoList_t devices;
factory.EnumerateDevices( devices );
if( devices.empty() ) { std::cerr << "basler-cat: no camera found" << std::endl; return 1; }
std::cerr << "basler-cat: will connect to the first of " << devices.size() << " found device(s):" << std::endl;
for( unsigned int i = 0; i < devices.size(); ++i ) { std::cerr << " " << devices[i].GetFullName() << std::endl; }
camera.Attach( transport_layer->CreateDevice( devices[0] ) );
}
if( verbose ) { std::cerr << "basler-cat: initialized camera" << std::endl; }
if( verbose ) { std::cerr << "basler-cat: opening camera " << camera.GetDevice()->GetDeviceInfo().GetFullName() << "..." << std::endl; }
camera.Open();
if( verbose ) { std::cerr << "basler-cat: opened camera " << camera.GetDevice()->GetDeviceInfo().GetFullName() << std::endl; }
Pylon::CBaslerGigECamera::StreamGrabber_t grabber( camera.GetStreamGrabber( 0 ) );
grabber.Open();
unsigned int channels;
switch( options.get_header().type ) // quick and dirty
{
case CV_8UC1:
channels = set_pixel_format_( camera, Basler_GigECamera::PixelFormat_Mono8 );
break;
case CV_8UC3:
channels = set_pixel_format_( camera, Basler_GigECamera::PixelFormat_RGB8Packed );
break;
default:
std::cerr << "basler-cat: type \"" << options.type << "\" not implemented or not supported by camera" << std::endl;
return 1;
}
unsigned int max_width = camera.Width.GetMax();
if( offset_x >= max_width ) { std::cerr << "basler-cat: expected --offset-x less than " << max_width << ", got " << offset_x << std::endl; return 1; }
camera.OffsetX.SetValue( offset_x );
width = ( ( unsigned long long )( offset_x ) + width ) < max_width ? width : max_width - offset_x;
camera.Width.SetValue( width );
unsigned int max_height = camera.Height.GetMax();
//if( height < 512 ) { std::cerr << "basler-cat: expected height greater than 512, got " << height << std::endl; return 1; }
// todo: is the colour line 2098 * 3 or ( 2098 / 3 ) * 3 ?
//offset_y *= channels;
//height *= channels;
if( offset_y >= max_height ) { std::cerr << "basler-cat: expected --offset-y less than " << max_height << ", got " << offset_y << std::endl; return 1; }
camera.OffsetY.SetValue( offset_y );
height = ( ( unsigned long long )( offset_y ) + height ) < max_height ? height : ( max_height - offset_y );
camera.Height.SetValue( height );
if( verbose ) { std::cerr << "basler-cat: set width,height to " << width << "," << height << std::endl; }
if( vm.count( "packet-size" ) ) { camera.GevSCPSPacketSize.SetValue( packet_size ); }
// todo: giving up... the commented code throws, but failure to stop acquisition, if active
// seems to lead to the following scenario:
// - power-cycle camera
// - view colour images: it works
// - view grey-scale images: it works
// - view colour images: it still displays grey-scale
//if( verbose ) { std::cerr << "basler-cat: getting aquisition status... (frigging voodoo...)" << std::endl; }
//GenApi::IEnumEntry* acquisition_status = camera.AcquisitionStatusSelector.GetEntry( Basler_GigECamera::AcquisitionStatusSelector_AcquisitionActive );
//if( acquisition_status && GenApi::IsAvailable( acquisition_status ) && camera.AcquisitionStatus() )
//{
// if( verbose ) { std::cerr << "basler-cat: stopping aquisition..." << std::endl; }
// camera.AcquisitionStop.Execute();
// if( verbose ) { std::cerr << "basler-cat: aquisition stopped" << std::endl; }
//}
// todo: a hack for now
GenApi::IEnumEntry* acquisitionStart = camera.TriggerSelector.GetEntry( Basler_GigECamera::TriggerSelector_AcquisitionStart );
if( acquisitionStart && GenApi::IsAvailable( acquisitionStart ) )
{
camera.TriggerSelector.SetValue( Basler_GigECamera::TriggerSelector_AcquisitionStart );
camera.TriggerMode.SetValue( frame_trigger.empty() ? Basler_GigECamera::TriggerMode_Off : Basler_GigECamera::TriggerMode_On );
}
GenApi::IEnumEntry* frameStart = camera.TriggerSelector.GetEntry( Basler_GigECamera::TriggerSelector_FrameStart );
if( frameStart && GenApi::IsAvailable( frameStart ) )
{
//if( frame_trigger.empty() ) { frame_trigger = line_trigger; }
if( frame_trigger.empty() )
{
camera.TriggerSelector.SetValue( Basler_GigECamera::TriggerSelector_FrameStart );
camera.TriggerMode.SetValue( Basler_GigECamera::TriggerMode_Off );
}
else
{
camera.TriggerSelector.SetValue( Basler_GigECamera::TriggerSelector_FrameStart );
camera.TriggerMode.SetValue( Basler_GigECamera::TriggerMode_On );
Basler_GigECamera::TriggerSourceEnums t;
if( frame_trigger == "line1" ) { camera.TriggerSource.SetValue( Basler_GigECamera::TriggerSource_Line1 ); }
if( frame_trigger == "line2" ) { camera.TriggerSource.SetValue( Basler_GigECamera::TriggerSource_Line2 ); }
if( frame_trigger == "line3" ) { camera.TriggerSource.SetValue( Basler_GigECamera::TriggerSource_Line3 ); }
else if( frame_trigger == "encoder" ) { camera.TriggerSource.SetValue( Basler_GigECamera::TriggerSource_ShaftEncoderModuleOut ); }
else { std::cerr << "basler-cat: frame trigger '" << frame_trigger << "' not implemented or invalid" << std::endl; return 1; }
camera.TriggerActivation.SetValue( Basler_GigECamera::TriggerActivation_RisingEdge );
camera.TriggerSelector.SetValue( Basler_GigECamera::TriggerSelector_LineStart );
camera.TriggerMode.SetValue( Basler_GigECamera::TriggerMode_On );
camera.TriggerActivation.SetValue( Basler_GigECamera::TriggerActivation_RisingEdge );
if( frame_trigger == "encoder" )
{
// todo: make configurable
camera.ShaftEncoderModuleLineSelector.SetValue( Basler_GigECamera::ShaftEncoderModuleLineSelector_PhaseA );
camera.ShaftEncoderModuleLineSource.SetValue( Basler_GigECamera::ShaftEncoderModuleLineSource_Line1 );
camera.ShaftEncoderModuleLineSelector.SetValue( Basler_GigECamera::ShaftEncoderModuleLineSelector_PhaseB );
camera.ShaftEncoderModuleLineSource.SetValue( Basler_GigECamera::ShaftEncoderModuleLineSource_Line2 );
camera.ShaftEncoderModuleCounterMode.SetValue( Basler_GigECamera::ShaftEncoderModuleCounterMode_FollowDirection );
camera.ShaftEncoderModuleMode.SetValue( Basler_GigECamera::ShaftEncoderModuleMode_ForwardOnly );
camera.ShaftEncoderModuleCounterMax.SetValue( encoder_ticks - 1 );
/// @todo compensate for mechanical jitter, if needed
/// see Runner_Users_manual.pdf, 8.3, Case 2
camera.ShaftEncoderModuleReverseCounterMax.SetValue( 0 );
camera.ShaftEncoderModuleCounterReset.Execute();
camera.ShaftEncoderModuleReverseCounterReset.Execute();
}
}
}
GenApi::IEnumEntry* lineStart = camera.TriggerSelector.GetEntry( Basler_GigECamera::TriggerSelector_LineStart );
if( lineStart && GenApi::IsAvailable( lineStart ) )
{
if( line_trigger.empty() )
{
camera.TriggerSelector.SetValue( Basler_GigECamera::TriggerSelector_LineStart );
camera.TriggerMode.SetValue( Basler_GigECamera::TriggerMode_Off );
}
else
{
camera.TriggerSelector.SetValue( Basler_GigECamera::TriggerSelector_LineStart );
camera.TriggerMode.SetValue( Basler_GigECamera::TriggerMode_On );
Basler_GigECamera::TriggerSourceEnums t;
if( line_trigger == "line1" ) { camera.TriggerSource.SetValue( Basler_GigECamera::TriggerSource_Line1 ); }
else if( line_trigger == "line2" ) { camera.TriggerSource.SetValue( Basler_GigECamera::TriggerSource_Line2 ); }
else if( line_trigger == "line3" ) { camera.TriggerSource.SetValue( Basler_GigECamera::TriggerSource_Line3 ); }
else if( line_trigger == "encoder" ) { camera.TriggerSource.SetValue( Basler_GigECamera::TriggerSource_ShaftEncoderModuleOut ); }
else { std::cerr << "basler-cat: line trigger '" << line_trigger << "' not implemented or invalid" << std::endl; return 1; }
camera.TriggerActivation.SetValue( Basler_GigECamera::TriggerActivation_RisingEdge );
camera.TriggerSelector.SetValue( Basler_GigECamera::TriggerSelector_LineStart );
camera.TriggerMode.SetValue( Basler_GigECamera::TriggerMode_On );
camera.TriggerActivation.SetValue( Basler_GigECamera::TriggerActivation_RisingEdge );
}
}
if( chunk_mode )
{
std::cerr << "basler-cat: setting chunk mode..." << std::endl;
if( !GenApi::IsWritable( camera.ChunkModeActive ) ) { std::cerr << "basler-cat: camera does not support chunk features" << std::endl; camera.Close(); return 1; }
camera.ChunkModeActive.SetValue( true );
camera.ChunkSelector.SetValue( Basler_GigECameraParams::ChunkSelector_Framecounter );
camera.ChunkEnable.SetValue( true );
camera.ChunkSelector.SetValue( Basler_GigECameraParams::ChunkSelector_Timestamp );
camera.ChunkEnable.SetValue( true );
camera.ChunkSelector.SetValue( Basler_GigECameraParams::ChunkSelector_LineTriggerIgnoredCounter );
camera.ChunkEnable.SetValue( true );
camera.ChunkSelector.SetValue( Basler_GigECameraParams::ChunkSelector_FrameTriggerIgnoredCounter );
camera.ChunkEnable.SetValue( true );
camera.ChunkSelector.SetValue( Basler_GigECameraParams::ChunkSelector_LineTriggerEndToEndCounter );
camera.ChunkEnable.SetValue( true );
camera.ChunkSelector.SetValue( Basler_GigECameraParams::ChunkSelector_FrameTriggerCounter );
camera.ChunkEnable.SetValue( true );
camera.ChunkSelector.SetValue( Basler_GigECameraParams::ChunkSelector_FramesPerTriggerCounter );
camera.ChunkEnable.SetValue( true );
parser = camera.CreateChunkParser();
if( !parser ) { std::cerr << "basler-cat: failed to create chunk parser" << std::endl; camera.Close(); return 1; }
std::cerr << "basler-cat: set chunk mode" << std::endl;
}
camera.ExposureMode.SetValue( Basler_GigECamera::ExposureMode_Timed );
if( vm.count( "exposure" ) ) { camera.ExposureTimeRaw.SetValue( exposure ); } // todo? auto exposure (see ExposureAutoEnums)
if( vm.count( "gain" ) )
{
camera.GainSelector.SetValue( Basler_GigECamera::GainSelector_All );
camera.GainRaw.SetValue( gain );
if( channels == 3 ) // todo: make configurable; also is not setting all not enough?
{
camera.GainSelector.SetValue( Basler_GigECamera::GainSelector_Red );
camera.GainRaw.SetValue( gain );
camera.GainSelector.SetValue( Basler_GigECamera::GainSelector_Green );
camera.GainRaw.SetValue( gain );
camera.GainSelector.SetValue( Basler_GigECamera::GainSelector_Blue );
camera.GainRaw.SetValue( gain );
}
}
if( vm.count( "line-rate" ) ) { camera.AcquisitionLineRateAbs.SetValue( line_rate ); }
if( vm.count( "test-colour" ) ) { camera.TestImageSelector.SetValue( Basler_GigECamera::TestImageSelector_Testimage6 ); }
else { camera.TestImageSelector.SetValue( Basler_GigECamera::TestImageSelector_Off ); }
unsigned int payload_size = camera.PayloadSize.GetValue();
if( verbose )
{
std::cerr << "basler-cat: camera mtu size: " << camera.GevSCPSPacketSize.GetValue() << std::endl;
std::cerr << "basler-cat: exposure: " << camera.ExposureTimeRaw.GetValue() << std::endl;
std::cerr << "basler-cat: payload size: " << payload_size << std::endl;
}
std::vector< std::vector< char > > buffers( 2 ); // todo? make number of buffers configurable
for( std::size_t i = 0; i < buffers.size(); ++i ) { buffers[i].resize( payload_size ); }
grabber.MaxBufferSize.SetValue( buffers[0].size() );
grabber.SocketBufferSize.SetValue( 127 );
if( verbose )
{
std::cerr << "basler-cat: socket buffer size: " << grabber.SocketBufferSize.GetValue() << std::endl;
std::cerr << "basler-cat: max buffer size: " << grabber.MaxBufferSize.GetValue() << std::endl;
}
grabber.MaxNumBuffer.SetValue( buffers.size() ); // todo: use --buffer value for number of buffered images
grabber.PrepareGrab(); // image size now must not be changed until FinishGrab() is called.
std::vector< Pylon::StreamBufferHandle > buffer_handles( buffers.size() );
for( std::size_t i = 0; i < buffers.size(); ++i )
{
buffer_handles[i] = grabber.RegisterBuffer( &buffers[i][0], buffers[i].size() );
grabber.QueueBuffer( buffer_handles[i], NULL );
}
if( chunk_mode )
{
snark::tbb::bursty_reader< ChunkPair > read( boost::bind( &capture_< ChunkPair >, boost::ref( camera ), boost::ref( grabber ) ), discard );
tbb::filter_t< ChunkPair, void > write( tbb::filter::serial_in_order, boost::bind( &write_, _1 ) );
snark::tbb::bursty_pipeline< ChunkPair > pipeline;
camera.AcquisitionMode.SetValue( Basler_GigECamera::AcquisitionMode_Continuous );
camera.AcquisitionStart.Execute(); // continuous acquisition mode
if( verbose ) { std::cerr << "basler-cat: running in chunk mode..." << std::endl; }
pipeline.run( read, write );
if( verbose ) { std::cerr << "basler-cat: shutting down..." << std::endl; }
camera.AcquisitionStop();
camera.DestroyChunkParser( parser );
}
else
{
snark::cv_mat::serialization serialization( options );
snark::tbb::bursty_reader< Pair > reader( boost::bind( &capture_< Pair >, boost::ref( camera ), boost::ref( grabber ) ), discard );
snark::imaging::applications::pipeline pipeline( serialization, filters, reader );
camera.AcquisitionMode.SetValue( Basler_GigECamera::AcquisitionMode_Continuous );
camera.AcquisitionStart.Execute(); // continuous acquisition mode
if( verbose ) { std::cerr << "basler-cat: running..." << std::endl; }
pipeline.run();
if( verbose ) { std::cerr << "basler-cat: shutting down..." << std::endl; }
camera.AcquisitionStop();
}
if( verbose ) { std::cerr << "basler-cat: acquisition stopped" << std::endl; }
is_shutdown = true;
while( !done ) { boost::thread::sleep( boost::posix_time::microsec_clock::universal_time() + boost::posix_time::milliseconds( 100 ) ); }
grabber.FinishGrab();
Pylon::GrabResult result;
while( grabber.RetrieveResult( result ) ); // get all buffers back
for( std::size_t i = 0; i < buffers.size(); ++i ) { grabber.DeregisterBuffer( buffer_handles[i] ); }
grabber.Close();
camera.Close();
if( verbose ) { std::cerr << "basler-cat: done" << std::endl; }
return 0;
}
catch( std::exception& ex ) { std::cerr << "basler-cat: " << ex.what() << std::endl; }
catch( ... ) { std::cerr << "basler-cat: unknown exception" << std::endl; }
return 1;
}
int main(int argc, char* argv[])
{
// The exit code of the sample application
int exitCode = 0;
// Automagically call PylonInitialize and PylonTerminate to ensure the
// pylon runtime system is initialized during the lifetime of this object.
Pylon::PylonAutoInitTerm autoInitTerm;
CTlFactory *_TlFactory = NULL;
int nTransportLayers;
TlInfoList_t transportLayers;
TlInfoList::const_iterator tl_it;
ITransportLayer* tl_;
Pylon::DeviceInfoList_t devices;
int nCameras = 0;
Pylon::DeviceInfoList_t::const_iterator it;
//CDeviceInfo devInfo;
Camera_t::DeviceInfo_t devInfo;
IPylonDevice *pDevice = NULL;
Camera_t *bCamera;
scoped_ptr<Camera_t> scoped_bCamera;
//FIXME: this arguments haven't been checked
Pylon::String_t pylon_camera_ip(argv[1]);
Pylon::String_t devInfoSource(argv[2]);
Pylon::String_t devInfoIterator("it");
int devInfoOptions = 0;
if (devInfoSource == "")
{
cout << "Second argument not specified, using default" << endl;
devInfoSource = devInfoIterator;
}
if (devInfoSource == "it")
{
cout << "To build the objects, the iterator reference will be used" << endl;
devInfoOptions = 1;
}
else if (devInfoSource == "devInfo")
{
cout << "To build the objects, the devInfo object will be used" << endl;
devInfoOptions = 2;
}
else
{
cout << "invalid device information source" << endl;
goto exit;
}
goto continueNormal;
exit://Moved from the bottom to avoid declarations with
//initialisations in the middle.
cout << "exit(" << exitCode << ")" << endl;
try
{
_TlFactory->ReleaseTl(tl_);
}
catch(exception& e)
{
cout << "couldn't release the transport layer" << endl;
}
try
{
scoped_bCamera.reset();
}
catch(exception& e)
{
cout << "couldn't reset the scoped_ptr" << endl;
}
cout << endl;
return exitCode;
continueNormal:
VersionInfo pylonVersionInfo;
cout << endl << "Working with Pylon version " \
<< pylonVersionInfo.getMajor() << " (" \
<< pylonVersionInfo.getVersionString() << ")" << endl;
cout << endl << "Get factory instance" << endl;
_TlFactory = &CTlFactory::GetInstance();
nTransportLayers = _TlFactory->EnumerateTls(transportLayers);
cout << "Available "<< nTransportLayers <<" transport layers" << endl;
for (tl_it = transportLayers.begin(); tl_it != transportLayers.end();tl_it++)
{
const Pylon::CTlInfo& tl_info = \
static_cast<const Pylon::CTlInfo&>(*tl_it);
cout << "\t- " << tl_info.GetFullName() << endl;
}
cout << endl << "Create a transport layer to access " \
<< Camera_t::DeviceClass() << " cameras" << endl;
tl_ = _TlFactory->CreateTl( Camera_t::DeviceClass() );
nCameras = tl_->EnumerateDevices( devices );
cout << "Found " << nCameras << " cameras" << endl;
if (nCameras == 0)
{
exitCode = -1;
goto exit;
}
cout << "\tIterate searching " << pylon_camera_ip << " camera"
<< endl;
for (it = devices.begin(); it != devices.end(); it++)
{
const Camera_t::DeviceInfo_t& gige_device_info = \
static_cast<const Camera_t::DeviceInfo_t&>(*it);
Pylon::String_t current_ip = gige_device_info.GetIpAddress();
cout << "\t\t- Found a " << gige_device_info.GetModelName() << " (" \
<< gige_device_info.GetSerialNumber() << ")" \
<< " with ip " << current_ip << endl;
if (current_ip == pylon_camera_ip)
{
cout << "\t\t\t** This is the camera wanted (" << current_ip << ") **"
<< endl;
devInfo = gige_device_info;
break;
}
}
if (it == devices.end())
{
cout << "\t\tCamera not found" << endl;
exitCode = -2;
goto exit;
}
cout << endl << "Wanted camera information:" << endl;
cout << "\t- FullName: \"" << devInfo.GetFullName() \
<< "\""<< endl;
cout << "\t- SerialNumber: \"" << devInfo.GetSerialNumber() \
<< "\""<< endl;
cout << "\t- ModelName: \"" << devInfo.GetModelName() \
<< "\""<< endl;
cout << "\t- DeviceClass: \"" << devInfo.GetDeviceClass() \
<< "\""<< endl;
cout << "\t- DeviceVersion: \"" << devInfo.GetDeviceVersion() \
<< "\""<< endl;
cout << "\t- DeviceFactory: \"" << devInfo.GetDeviceFactory() \
<< "\""<< endl;
cout << "\t- Interface: \"" << devInfo.GetInterface() \
<< "\""<< endl;
cout << endl << "Connect to the Camera for further control" << endl;
try
{
cout << "Build and attach in one step" << endl;
if (devInfoOptions == 1)
{
bCamera = new Camera_t(_TlFactory->CreateDevice(*it));
}
else
{
bCamera = new Camera_t(_TlFactory->CreateDevice(devInfo));
}
scoped_bCamera.reset(bCamera);
}
catch(exception& e)
{
cout << "\tIt doesn't work!\n\t" << e.what() << endl \
<< "Try an alternative" << endl;
try
{
cout << "\tFirst build..." << endl;
bCamera = new Camera_t();
scoped_ptr<Camera_t> camera(new Camera_t());
scoped_bCamera.reset(bCamera);
cout << "\tThen attach..." << endl;
if (devInfoOptions == 1)
{
bCamera->Attach(_TlFactory->CreateDevice(*it));
}
else
{
bCamera->Attach(_TlFactory->CreateDevice(devInfo));
}
}
catch(exception& e)
{
cout << "\t\tFailed!\n\t" << e.what() << endl;
exitCode = -3;
goto exit;
}
}
if (scoped_bCamera.get() == NULL)
{
cout << "\t* Camera object points to NULL" << endl;
exitCode = -4;
goto exit;
}
else if (not scoped_bCamera.get()->IsAttached())
{
cout << "\t* Camera object build but not attached to a Device object" \
<< endl;
exitCode = -5;
goto exit;
}
pDevice = scoped_bCamera.get()->GetDevice();
if (!pDevice)
{
cout << "\tPylon Device points to NULL" << endl;
exitCode = -6;
goto exit;
}
cout << endl << "Play with the build objects" << endl;
cout << "\t- Pylon device has " << pDevice->GetNumStreamGrabberChannels() \
<< " stream grabber channels" << endl;
Camera_t::TlParams_t TlParams(scoped_bCamera->GetTLNodeMap());
cout << "\t- TL read timeout:" << dec << TlParams.ReadTimeout.GetValue() \
<< endl;
cout << "\t- TL write timeout:" << dec << TlParams.WriteTimeout.GetValue() \
<< endl;
cout << "\t- TL heartbeat timeout:" << dec \
<< TlParams.HeartbeatTimeout.GetValue() << endl;
cout << "\t- Open Pylon Device" << endl;
pDevice->Open();
if (not scoped_bCamera.get()->IsOpen())
{
cout << "\t* Open the Device object didn't show the Camera Object open" \
<< endl;
exitCode = -7;
goto exit;
}
cout << endl << "Information requested directly to the camera:" << endl;
cout << "\t\t- Firmware version: " \
<< scoped_bCamera.get()->DeviceFirmwareVersion.GetValue() << endl;
//close: //TODO: label to be used in the checks after the communication is open.
cout << "\tClose Pylon Device" << endl;
pDevice->Close();
cout << "\tDetele Pylon Device object" << endl;
_TlFactory->DestroyDevice(pDevice);
goto exit;//with exitCode = 0, that means "everything went well"!
}
